The Microbial World and You

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The Microbial World and You

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Title: The Microbial World and You

1
1

The Microbial World and You

Instructor Dr. Ahmad Saleh
2
Microbes in Our Lives

Microbiology is the study of microorganisms.
The overall theme of the Microbiology course is
to study the relationship between microbes and
our lives.
Microorganisms (microbes) are organisms that are
too small to be seen with the unaided eye, and
usually require a microscope to be seen.
This relationship involves harmful effects such
as diseases and food spoilage as well as many
beneficial effects.
Germ refers to a rapidly growing cell.
Microorganisms include
Bacteria
Fungi (yeasts and molds)
Microscopic Algae
Protozoa
Viruses, Viroids, Prions
(Non-living infectious agents)

3
Microbes in Our Lives

These small organisms are usually associated with
major diseases such as AIDS, uncomfortable
infections, or food spoilage.
However, the majority of microorganisms make
crucial contributions to the to the welfare of
the worlds inhabitants by maintaining balance of
living organisms and chemicals in our
environment.
Therefore, Microorganisms are essential for life
on earth.
They have important beneficial biological
functions
Photosynthesis Marine and freshwater MO (Algae
and some bacteria) capture energy from sunlight
and convert it to food, forming the basis of the
food chain in oceans, lakes, and rivers and
generates oxygen which is critical for life on
Earth.
Decomposers Soil microbes break down dead and
decaying matter and recycle chemical elements
that can be used by other organisms.
Nitrogen Fixation Some bacteria can take
nitrogen from air and incorporate it into organic
compounds in soil, water, and air.

4
Microbes in Our Lives

Digestion Human and many other animals have
microorganisms in their digestive tract, that are
essential for digestion and vitamin synthesis.
Cellulose digestion by ruminants (cows, rabbits,
etc.)
Synthesis of Vitamin K (for blood clotting) and
Vitamin B (for metabolism) in humans.
Synthesis of chemical products MOs have many
commercial applications, such as the synthesis of
acetone, organic acids, enzymes, alcohols.
Medicine Many antibiotics and other drugs are
naturally synthesized by microbes.
Penicillin is made by a mold.
Food industry many important foods and beverages
are made with microbes vinegar, pickles,
alcoholic beverages, green olives, soy sauce,
buttermilk, cheese, yogurt, and bread.

5
Microbes in Our Lives

Genetic engineering recombinant microbes produce
important
Medical and therapeutic products human growth
hormone, insuline, blood clotting factor,
recombinant vaccines, monoclonal antibodies,etc.
Commercial products cellulose, digestive aids,
and drain cleaner.
Medical Research Microbes are well suited for
biological and medical research for several
reasons
Relatively simple and small structures, easy to
study
Genetic material is easily manipulated.
Can grow a large number of cells very quickly and
at low cost.
Short generation times make them very useful to
study genetic changes.
Though only a minority of MOs are pathogenic
(disease-producing), practical knowledge of
microbes is necessary for medicine and related
heath sciences.
Ex. Hospital workers must be able to protect
patients from common microbes that are normally
harmless but pose a threat to the sick and
injured.

6
Knowledge of Microorganisms

Today we understand that MOs are almost
everywhere !
Yet not long ago, before the invention of the
microscope, microbes were unknown to scientists
and
Thousands of people died in devastating
epidemics, the causes of which were NOT
understood.
Entire families died because vaccinations and
antibiotics were NOT available to fight
infections.
Therefore, knowledge of MOs allows humans to
Prevent disease occurrence
Prevent food spoilage
Led to aseptic techniques to prevent
contamination in medicine and in microbiology
laboratories.

7
Naming and Classifying Microorganisms

Linnaeus established the system of scientific
nomenclature (naming) of organisms in 1735.
Latin was the language traditionally used by
scholars.
Scientific nomenclature assigns each organism two
names (Binomial)
The genus is the first name and is always
capitalized.
The specific epithet (species name) follows and
is not capitalized.
Are italicized or underlined.
The genus is capitalized and the specific epithet
is lower case.
Are Latinized and used worldwide.
May be descriptive or honor a scientist.

8
Naming and Classifying Microorganisms

Staphylococcus aureus
Describes the clustered arrangement of the cells
(staphylo), (coccus) indicates spherical shape,
and the golden color of the colonies (aur-).
Escherichia coli
Honors the discoverer, Theodor Escherich, and
describes the bacteriums habitatthe large
intestine or colon.
After the first use, scientific names may be
abbreviated with the first letter of the genus
and the specific epithet
Staphylococcus aureus and Escherichia coli are
found in the human body. S. aureus is on skin and
E. coli in the large intestine.

9
Types of Microorganisms BACTERIA (Sing.
Bacterium)

Relatively Simple, single-celled (unicelluar)
organisms.
Prokaryotic (their genetic material is not
enclosed in nuclear membrane)
Prokaryotes include the bacteria and archaea
Bacteria appear in one of several shapes
Bacillus (rodlike), b. coccus (spherical),
spiral (corkscrew or curved),
some are star-shaped or square.
Individual bacteria may form pairs, chains,
clusters, or other groupings.
Enclosed in cell walls largely composed of
peptidoglycan (carbohydrate and protein complex).
Reproduce by binary fission (division into two
equal cells)
For nutrition, most bacteria use organic
chemicals derived from dead or living organisms.
Some bacteria produce their food by
photosynthesis, and some can derive nutrition
from inorganic substances.
Many bacteria can swim by using flagella (moving
appendages).

10
Types of MicroorganismsARCHAEA

Consists of prokaryotic cells
If they have cell walls, they lack peptidoglycan
Archaea are not known to cause disease in humans.
Live in extreme environments
Are divided into three main groups
Methanogens produce methane as waste product
from respiration.
Extreme halophiles Salt loving, live in
extremely salty environments such as the Great
Salt Lake and the Dead Sea.
Extreme thermophiles Heat loving, live in hot
sulfurous water such as hot springs.

11
Types of Microorganisms FUNGI (S. Fungus)

Eukaryotic (have a distinct nucleus containing
the cells genetic material surrounded by a
nuclear membrane)
Organisms in kingdom Fungi may be Unicellular or
multicellular
Multicellular fungi, such as mushroom look like
plants, but can not carry out photosynthesis.
True fungi have cell walls composed of chitin.
The unicellular fungi, yeasts, are oval MOs that
are larger than bacteria.
The most typical fungi are molds, composed of
visible masses of filaments (hyphae) called
mycelia.
Use organic chemicals for energy, can not carry
out photosynthesis.
Fungi can reproduce sexually and asexually
They obtain nutrients by absorbing solutions of
organic material from environment soil, sea
water, fresh water, or animal or plant host.
Organisms called slime molds have characteristics
of both fungi and ameobas.

12
Types of Microorganisms PROTOZOA (S. Protozoan)

Unicellular, eukaryotes microbes.
Protozoa move by
Pseudopods extensions of the cytoplasm like
Ameoba.,
Flagella long appendages for locomotion like
Trypanosoma.
Cilia numerous shorter appendages for locomotion
like Paramecium.
Protozoa have a variety of shapes.
Live as free entities or as parasites (organisms
that derive nutrients from living hosts).
Absorb or ingest organic compounds from their
environment)
Protozoa can reproduce sexually and asexually.

Figure 1.1c
13
Types of Microorganisms ALGAE (S. Alga)

Photosynthetic eukaryotes
Have wide variety of shapes
Reproduce sexually and asexually.
Unicellular and multicelluar.
The cell walls of many algae, like those of
plants,
are composed of cellulose (a carbohydrate).
Algae are aundant in fresh and salt water, in
soil, and in association with plants.
As photosynthesizers, algae need light, water,
and carbon dioxide for food production and
growth.
Produce molecular oxygen and organic compounds
(carbohydrates) that are used by other organisms,
including animals.
They play an important role in the balance of
nature.

14
Types of MicroorganismsVIRUSES

So small that can be seen only with electron
microscope.
Acellular (not cellular).
Structurally very simple, a virus particle
contains
a core made only of one type of nucleic acid,
either DNA or RNA.consist of DNA or RNA
core
The core is surrounded by a protein coat.
Sometimes the coat is enclosed in a lipid
envelope.
Viruses can reproduce only by using the cellular
machinery of other organisms.
Obligatory intracellular parasites (replicate
only when they are in a living host cell)

15
Multicellular Animal Parasites

Multicellular animal parasites are not strictly
MOs.
They are of medical importance.
They are eukaryotic organisms.
Multicellular animals
Parasitic flatworms and round worms are called
helminths.
During some stages of their life cycles,
helminths are microscopic in size.

Figure 12.28a
16
Classification of Microorganisms

Before the existence of microbes was known, all
organisms were grouped into either the animal
kingdom or the plant kingdom.
In 1978, Carl Woese, devised a system of
classification based on the cellular organization
of organisms.
It groups all organisms in three domains as
follows
Bacteria (cell walls contain a protein-carbohydrat
e complex called peptidoglycan)
Archaea (cell walls, if present, lack
peptidoglycan)
Eukarya, which includes the following kingdoms
Protists (slime molds, protozoa, and algae)
Fungi (unicellular yeasts, multicellular molds,
and mushrooms)
Plants (includes mosses, ferns, conifers, and
flowering plants)
Animals (includes sponges, worms, insects, and
vertebrates).

17
A Brief History of Microbiology

The science of Microbiology dates back only two
hundred years.
However, microorganisms have been around for
thousands of years.
Ancestors of bacteria were the first living cells
to appear on Earth.
The first microbes (animalcules) were observed in
1673 by Leeuwenhoek.
In 1665, Robert Hooke reported that living things
were composed of little boxes or cells, with the
help of a relatively crude
microscope.
In 1858, Rudolf Virchow said cells arise from
preexisting cells.
Cell theory All living things are composed of
cells
and come from preexisting cells.
1673-1723 Antoni van Leeuwenhoek described live
microorganisms (animalcules) that he
observed in
teeth scrapings, rain water.

18
The Debate Over Spontaneous Generation

After van Leeuwenhoek discovered the invisible
world of microorganisms, the scientific community
of that time became interested in the origins of
these tiny living things.
Not much more than 100 years ago, many scientists
and philosophers believed that some forms of life
could arise spontaneously from nonliving matter,
they called this the hypothesis of spontaneous
generation.
Therefore, people commonly believed that toads,
snakes, and mice could be born of moist soil
that flies could emerge from manure and that
maggots, the larvae of flies, could arise from
decaying corpses.
According to spontaneous generation, a vital
force forms life.
The alternative hypothesis, that the living
organisms arise from preexisting life, is called
biogenesis.

19
Evidence PRO and CONRedis Experiments

In 1668 A strong opponent of SG, Francisco Redi
set out to demonstrate that maggots did not arise
spontaneously from decaying meat.
Redi filled two jars with decaying meat.
The first was left unsealed the flies thaid
their eggs on the meat, and the eggs developed
into larvae.
The second jar was sealed and, because the flies
couldnot lay their eggs on the meat, no maggots
appeared.
Redis antagonists were not convinced they
claimed that fresh air was needed for spontaneous
generation.
Redi set up a second experiment, in which
a jar was covered with a fine net instead of
being sealed.
No larvae appeared in the gauze-covered jar, even
though air was present.
Maggots appeared only when flies were allowed to
leave eggs on the meat.
Redis results blowed the belief that large forms
of life could arise from nonlife.

20
Evidence Pro and ConNeedhams and Spallanzanis
Exp.

However, many scientists still believed that
small organisms such as van Leeuwenhoeks
animalcules were simple enough to be generated
from nonliving material.
In 1745 John Needham performed an experiment
which seemed to strengthen the SG of MOs.
He heated nutrient fluids (chicken broth)
Poured them into covered flasks
The cooled solution were soon teeming with
microorganisms.
Needham claimed that microbes developed
spontaneously from the fluids.
20 years later, Lazzaro Spallanzani, suggested
that MOs from the air probably had entered
Needhams solutions after they were boiled.
Spallanzani showed that nutrients fluids heated
after being sealed in a flask did not develop
microbial growth.
Needham responded by claiming the vital force
was destroyed by heat and kept out of the flasks
by the seals.

21
Evidence Pro and Con

The vital force principle was strengthened
when Anton Lavoisier showed the importance of
oxygen to life.
Therefore, Spallanzanis observations were
criticized on the grounds that there was not
enough oxygen in the sealed flasks to support
microbial growth.
In 1858, Rudolw Virchow challenged SG with the
concept of Biogenesis, the claim that living
cells can arise only from preexisting living
cells.
In 1861 Louis Pasteur demonstrated that
microorganisms are present in the air and can
contaminate sterile solutions, but air itself
does not create microbes.
He filled several short-necked flasks with beef
broth and boiled them.
Some were left open and allowed to cool.
In a few days, these flasks were found to be
contaminated with microbes.
The sealed after-boiling flasks were free of
microorganisms.
Pasteur reasoned that microbes in the air were
the agents responsible for contaminating
nonliving matter.

22
The Theory of Biogenesis

Pasteur next placed broth in open-ended
long-necked flasks and bent the necks into
S-shaped curves.
The contents of these flasks were then boiled and
cooled.
The broth of in the flasks did not decay and
showed no signs of life.
Pasteurs S-shaped neck allowed air to pass into
the flask, but trapped the airborne MOs that
might contaminate the broth.

Figure 1.3
23
Pasteurs Findings

Pasteur showed that MOs can be present in
nonliving matter- on solids, in liquids, and in
the air.
He demonstrated that microbial life can be
destroyed by heat and devised methods to block
access of airborne MOs to nutrients.
These discoveries forms the basis of aseptic
techniques (techniques that prevent contamination
by unwanted MOs.), which are now the standard
practice in laboratory and many medical
procedures.
Pasteurs work provided evidence that MOs can not
originate from mystical forces preset in
nonliving materials.
Scientists now believe that a form of spontaneous
generation probably did occur on primitive Earth
when life first began.
Pasteur showed that microbes are responsible for
fermentation.

24
The Golden Age of Microbiology

The period from 1857-1914, has been named the
Golden Age of Microbiology.
During this period, rapid advances headed by
Pasteur and Robert Koch, led to the establishment
of microbiology as a science.
Beginning with Pasteurs work, discoveries
included
The agents of many diseases.
The role of immunity in the prevention and cure
of diseases.
The relationship between microbes and disease.
Antimicrobial drugs
Improved the techniques for microscopy and
culturing microorganisms.
Development of vaccines and surgical techniques.
Studying the chemical activities of
microorganisms.

25
Fermentation and Pasteurization

At that time, many scientists believed that air
converted the sugars in beverages into alcohols.
Pasteur found instead that microbes called yeasts
convert the sugars to alcohols in the absence of
air in a process called fermentation.
Fermentation is the conversion of sugar to
alcohol to make beer and wine.
Souring and spoilage are caused by different MOs
called bacteria.
In the presence of air, bacteria change the
alcohol in the beverage into vinegar (acetic
acid).
Pasteurs solution to the spoilage problem was to
heat the beer and wine just enough to kill most
of the bacteria that caused the spoilage in a
process called pasteurization.
Pasteurization is now commonly used to reduce
spoilage and kill potentially harmful bacteria in
milk as well as in some alcoholic drinks.
Showing the connection between spoilage of food
and MOs was a major step towards establishing the
relationship between disease and microbes.

26
The Germ Theory of Disease

Until relatively recently, the fact that many
kinds of diseases are related to MOs was unknown.
Before the time of Pasteur, effective treatments
for many diseases were discovered by trial and
error, but the causes of the diseases were
unknown.
The realization that yeasts play a crucial role
in fermentation was the first link between the
activity of a MO and physical and chemical
changes in organic materials.
This discovery alerted scientists that MOs might
have similar relationships with plants and
animals- specially, that MOs might cause
diseases.
This idea was known as the germ theory of
disease.
Many people did not accept this theory at that
time, because for centuries disease was believed
to be punishment for individuals crimes and
misdeeds.
Most people in Pasteurs time found it
inconceivable that invisible microbes could
travel through the air to infect plants and
animals, or remain on clothing and bedding to be
transmitted from one person to another.

27
The Germ Theory of Disease

1835 Agostino Bassi showed that a silkworm
disease was caused by a fungus.
1865 Pasteur found that another recent silkworm
disease was caused by a protozoan.
1840s Ignaz Semmelwise advocated hand washing to
prevent transmission of childbirth fever from one
obstetrical patient to another.
1860s Joseph Lister used a chemical disinfectant
(phenol) to prevent surgical wound infections
after looking at Pasteurs work showing microbes
are in the air, can spoil food, and cause animal
diseases.
1876 Robert Koch proved for the first time that
a bacterium causes anthrax and provided the
experimental steps, Kochs postulates, to prove
that a specific microbe causes a specific disease.

28
Vaccination

1796 Edward Jenner found a way to protect people
from smallpox almost 70 years before Koch
established that microorganism causes anthrax.
He inoculated a healthy 8-years-old volunteer
with cowpox virus. The person was then protected
from cowpox and smallpox.
The process was called Vaccination, derived from
Latine word vacca for cow.
The protection from disease provided by
vaccination or by recovery from the disease
itself is called immunity.
In about 1880, Pasteur discovered why vaccination
work by working on cholera vaccination.
Pasteur used the term vaccine for cultures of
avirulent microorganisms used for preventive
inoculation.
Some vaccines are still produced from avirulent
microbial strains, others are made from killed
virulent microbes, from isolated components of
virulent MOs, or by genetic engineering
techniques.

29
The Birth of Modern Chemotherapy

Treatment of disease by using chemical substances
is called chemotherapy.
Chemotherapeutic agents prepared from chemicals
in the laboratory are called synthetic drugs.
Chemotherapeutic agents produced naturally by
bacteria and fungi to act against other MOs are
called antibiotics.
The success of chemotherapy is based on the fact
that some chemicals are more poisonous to MOs
than to the hosts infected by the microbes.
Quinine from tree bark was long used to treat
malaria.
1910 Paul Ehrlich developed the first synthetic
drug, Salvarsan, to treat syphilis. (the magic
bullet!)
1930s Several other synthetic drugs derived from
dyes that could destroy MOs were developed.
Sulfonamides (sulfa drugs) were synthesized at
about the same time.

30
The Birth of Modern Chemotherapy

1928 Alexander Fleming discovered the first
antibiotic.
On a contaminated plate, around the mold
(Penicillium) was a clear area where bacterial
growth had been inhibited.
He observed that the Penicillium mold made an
antibiotic, penicillin, that killed S. aureus.
1940s Penicillin was tested clinically and mass
produced.
Since then, thousands of antibiotics have been
discovered.
Antibiotics and other chemotherapeutic drug faces
many problem
Toxicity to humans in practical use, specially
antiviral drugs (why ?)
The emergence and spread of new varieties
of MOs that are resistant to antibiotics.
(due to bacterial enzymes that inactivate
antibiotics,
or prevention of Abt. From entering the microbe.)

Figure 1.5
31
Modern Developments in MicrobiologyBranches of
Microbiology

Bacteriology is the study of bacteria.
Began with the van Leeuwenhoeks first
examination of tooth scrapings.
New pathogenic bacteria are still discovered
regularly.
Many bacteriologists, look at the roles of
bacteria in food and environment.
Mycology is the study of fungi.
Includes medical, agricultural, and ecological
branches.
Fungal infections accounting for 10 of hospital
acquired infections.
Parasitology is the study of protozoa and
parasitic worms.
Recent advances in genomics, the study of all of
an organisms genes, have provided new tools for
classifying microorganisms.
Previously these MOs were classified according to
a limited number of visible characteristics.

32
Modern Developments in MicrobiologyBranches of
Microbiology

Immunology is the study of immunity.
Vaccines and interferons are being investigated
to prevent and cure viral diseases.
Vaccines are now available for numerous diseases,
including measles, rubella (German measles),
mumps, chickenpox, pneumococcal pneumonia,
tetanus, tuberculosis, whooping coughs, polio,
and hepatitis B.
Smallpox was eradicated due to effective
vaccination and polio is expected to.
Interferons, substances produced by the bodys
own
immune system, inhibit the replication of
viruses and
are used to treat viral diseases and cancer.
The use of immunology to identify and classify
some
bacteria according to serotypes (variants
within
a species) based on certain components in
the cell
walls of the bacteria, was proposed by
Rebecca
Lancefield in 1933.

Figure 1.4 (3 of 3)
33
Modern Developments in MicrobiologyBranches of
Microbiology

Virology is the study of viruses.
In 1892, Dimitri Iwanowski reported that the
organism that caused mosaic disease of tobacco
was so small that is passed the bacterial
filters.
In 1935, Wendell Stanely demonstrated that the
organism , called tobacco mosaic virus (TMV), was
different from other microbes, so simple, and
composed of only nucleic acid core and protein
core.
In 1940s, the development of electron microscope
enabled the scientists to observe the structure
and activity of viruses in detail.

34
Modern Developments in MicrobiologyBranches of
Microbiology

Recombinant DNA Technology
In the 1960s, Paul Berg inserted animal DNA into
bacterial DNA and the bacteria produced an animal
protein.
Recombinant DNA is DNA made from two different
sources.
Recombinant DNA technology, or genetic
engineering, involves microbial genetics and
molecular biology.
Using microbes
Beadle and Tatum showed that genes encode a
cells enzymes (1942).
Avery, MacLeod, and McCarty showed that DNA was
the hereditary material (1944).
Lederberg and Tatum discovered that genetic
material could be transferred from one bacterium
to another by conjugation (1946).
Watson and Crick proposed a model for the
structure of DNA (1953).
Jacob and Monod discovered the role of mRNA in
protein synthesis (1961).

35
Microbes and Human Welfare

Only minority of all MOs are pathogenic.
Microbes that cause food spoilage are also a
minority.
The vast majority of microbes benefit humans,
other animals, and plants in many ways.
RECYCLING VITAL ELEMENTS
In 1880s, Beijerinck and Winogradsky showed how
bacteria help recycle vital elements between the
soil and the atmosphere.
Microbial ecology the study of the relationship
between microorganisms and their environment.
Microorganisms recycle carbon, nitrogen, sulfur,
oxygen, and phosphorus into forms that can be
used by plants and animals.
Bacteria and fungi, return CO2 to the atmosphere
when decomposing organic wastes and dead plants
and animals.
Algae, cyanobacteria, and plants use CO2 to
produce carbohydrates.

36
Microbes and Human Welfare

SEWAGE TREATMENT Using microbes to recycle
water.
Recycling water and prevent the pollution of
rivers and oceans
Bacteria degrade organic matter in sewage (99
water), producing such by-products as carbon
dioxide, nitrates, phosphates, sulfates, ammonia,
hydrogen sulfide, and methane.
BIOREMEDIATION Using microbes to clean up
pollutants.
In 1988, microbes began used to clean up
pollutants and
toxic wastes produced by various industrial
processes.
Bacteria degrade or detoxify pollutants such as
oil and
mercury.
In addition, bacterial enzymes are used in drain
cleaners to remove clogs
Such bioremedial microbes are Pseudomonas and
Bacillus, their enzymes used in household
detergents.

UN 2.1
37
Microbes and Human Welfare

INSECT BEST CONTROL BY MOs
Insect pest control is important for both
agriculture and the prevention of human diseases.
Bacillus thuringiensis infections are fatal for
many insects but harmless to other animals,
including humans, and to plants.
The bacteria produce protein crystals that are
toxic to the digestive systems of the insects.
The toxin gene has been inserted into some plants
to make them insect resistant.
Microbes that are pathogenic to insects are
alternatives to chemical pesticides in preventing
insect damage to agricultural crops, disease
transmission, and avoid harming the environment.

38
Microbes and Human Welfare

MODERN BIOTECHNOLOGY AND RECOMBINANT DNA
TECHNOLOGY
Biotechnology, the use of microbes to produce
foods and chemicals, is centuries old.
Genetic engineering is a new technique for
biotechnology. Through genetic engineering,
bacteria and fungi can produce a variety of
proteins including vaccines and enzymes.
Recombinant DNA techniques have been used to
produce a number of natural proteins, vaccines,
and enzymes.
The very exciting and important outcome of
recombinant DNA techniques is Gene Therapy
inserting a missing gene or replacing a defective
one in human cells by using a harmless virus to
carry the missing or new gene into certain host
cells.
Genetically modified bacteria are used to protect
crops from insects, from freezing, and to improve
the appearance, flavor, and shelf life of fruits
and vegetables. (more Drought resistance and
temperature tolerance)

39
Microbes and Human DiseaseNORMAL MICROBIOTA

We all live in a world filled with microbes, and
we all have a variety of microorganisms on and in
our bodies.
Microbes normally present in and on the human
body are called normal microbiota, or flora.
Bacteria were once classified as plants giving
rise to use of the term flora for microbes.
This term has been replaced by microbiota.
The normal microbiota not only harmless, but also
benefit us.
Some protect us against disease by preventing the
over-growth of harmful microbes.
Others produce useful substances such as vitamine
K and B.
Unfortunately, under some circumstances normal
microbiota can make us sick or infect people we
contact.

40
Microbes and Human DiseaseINFECTIOUS DISEASES

An infectious disease is one in which pathogens
invade a susceptible host, such as a human or
animal.
The pathogen carries out at least part of its
life cycle inside the host, and disease
frequently results.
When a pathogen overcomes the hosts resistance,
disease results.
Many mistakenly believed that infectious diseases
were under control
Malaria would be eradicated by killing mosquitoes
by DDT.
A vaccine would prevent diphtheria.
Improved sanitation measures would help prevent
cholera transmission.
Recent outbreaks of such infectious diseases
indicates that not only they are not
disappearing, but seem to be reemerging and
increasing.
In addition, a number of new diseases -Emerging
infectious diseases (EID)-have cropped up in
recent years

41
Microbes and Human DiseaseEMERGING INFECTIOUS
DISEASES

Emerging infectious diseases (EID) are diseases
that are new or changing and are increasing or
have the potential to increase in incidence in
the near future.
Some factors that have contributed to the
emergence of EIDs
Evolutionary changes in existing organisms.
The spread of known diseases to new geographic
regions or populations by modern transportation.
Increased human exposure to new, unusual
infectious agents.
West Nile encephalitis
Caused by West Nile virus
First diagnosed in the West Nile region of Uganda
in 1937
Appeared in New York City in 1999
Bovine spongiform encephalopathy
Caused by prion
Also causes Creutzfeldt-Jakob disease (CJD)
New variant CJD in humans is related to cattle
feed from infected sheep.